Experimental evidence for the evolution of numerous,tiny sperm via sperm competition

Sperm competition, when sperm from different males compete to fertilize a female's ova, is a widespread and fundamental force in the evolution of animal reproduction. The earliest prediction of sperm competition theory was that sperm competition selected for the evolution of numerous, tiny sperm, and that this force maintained anisogamy. Here, we empirically test this prediction directly by using selective breeding to generate controlled and independent variance in sperm size and number traits in the cricket Gryllus bimaculatus. We find that sperm size and number are male specific and vary independently and significantly. We can therefore noninvasively screen individuals and then run sperm competition experiments between males that differ specifically in sperm size and number traits. Paternity success across 77 two-male sperm competitions (each running over 30-day oviposition periods) shows that males producing both relatively small sperm and relatively numerous sperm win competitions for fertilization. Decreased sperm size and increased sperm number both independently predicted sperm precedence. Our findings provide direct experimental support for the theory that sperm competition selects for maximal numbers of miniaturized sperm. However, our study does not explain why G. bimaculatus sperm length persists naturally at approximately 1 mm; we discuss possibilities for this sperm size maintenance.     

Testis size,epididymis weight,and sperm competition in rhesus macaques

The intensity of sperm competition is often measured using the gonadosomatic index (testes/body weight). But sperm competition could be mediated more by size of the epididymis than by size of the testicles, and little information is available on the relationship between testicular and epididymal size. We found that both organs were positively correlated in size among male rhesus macaques. Body weight accounted for over 70% of the variance in testicle size and volumetric estimates of testicle size accurately reflected testicle weight. We conclude that methods for ascertaining testicle size are accurate, but the covariation in size between testicles and epididymis will hamper understanding of the physiological mechanisms involved in sperm competition in primates. © 1993 Wiley-Liss, Inc.     

Female genotype affects male success in sperm competition

The central question addressed by most studies of sperm competition is: ''what determines which male''s sperm are used at fertilization?'' Empirical and theoretical studies that address this question have traditionally focused on adaptations which enhance male fertilization success while treating the female as a receptacle in which sperm competition is played out. Here we provide evidence which suggests that female genotype strongly influences the outcome of sperm competition. When the sperm of two males are in competition the proportion of offspring fathered by the second male to mate (P₂) was found to be highly repeatable only if the male pair were mated to three different, but genetically similar females (full-sisters to each other; unrelated to either of the males). In contrast, if a male pair were mated to three females that were unrelated then P₂ was either non-repeatable or marginally repeatable. We also show that male success in sperm competition is determined, to a large extent, by gamete and/or male–female compatibility. This conclusion is derived from the observation that P₂ was repeatable among full-sisters mated to different, yet genetically similar male pairings, whilst P₂ was non-repeatable among full-sisters mated to different, genetically distinct male pairings.     

Male and female effects on sperm precedence in the giant sperm species <Emphasis Type="Italic">Drosophila bifurca</Emphasis>

Sperm competition is expected to be a driving force in sexual selection. In internally fertilized organisms, it occurs when ejaculates from more than one male are present simultaneously within the female’s reproductive tract. It has been suggested that greater sperm size may improve the competitive ability of sperm, but studies provide contradictory results depending on the species. More recently, the role of females in the evolution of sperm morphology has been pointed out. We investigate here the male and female effects that influence sperm precedence in the giant sperm species, Drosophila bifurca Patterson & Wheeler. Females were mated with two successive males, and the paternity outcomes for both males were analyzed after determining sperm transfer and storage. We found very high values of last male sperm precedence, suggesting a strong interaction between rival sperm. However, the data also indicate high frequencies of removal of the sperm of the first male from the female reproductive tract prior to any interaction with the second male. This implies that successful paternity depends mainly on successful sperm storage. Knowing what happens to the sperm within females appears to be a prerequisite for disentangling post-copulatory sexual interactions between males and females.     

Predicting variation in sperm precedence

Sperm competition theory predicts that males are adapted for success in sperm competition by the production of large numbers of sperm. This is supported by both inter- and intraspecific studies showing that males mating under high sperm competition risk increase investment in sperm production. Such an increase in sperm production is an advantage if sperm mix randomly or if sperm displacement occurs. When two males mate with the same female, the measurement of the proportion of eggs fertilized by the second male to mate (termed P₂) has been used to help elucidate sperm competition mechanisms. P₂ is usually quoted as a mean value, with little attention being paid to its variance, although P₂ estimates are notoriously variable. By predicting an expected variance for P₂, additional information on sperm competition mechanisms may be obtained. Here we present a technique for analysing the variance in P₂ when a given mechanism of P₂ is assumed. We apply this technique to P₂ data collected from Plodia interpunctella (Lepidoptera, Pyralidae), assuming a ''fair raffle'' mechanism of sperm competition. We compare observed distributions of P₂ with theoretical distributions generated assuming random mixing of two ejaculates drawn randomly from a population of known mean and variance in sperm numbers. Ejaculates of known size were obtained by counting the number of sperm ejaculated by males mating for the first (large ejaculate) or second (small ejaculate) time. Females either received two small or one small and one large ejaculate, and the distribution of P₂ (estimated using the sterile male technique) was compared with our theoretical predictions. The observed variance in P₂ was greater than our model prediction, thus we conclude that sperm from P. interpunctella do not mix randomly before fertilization. <br>     

Human sperm competition: testis size, sperm production and rates of extrapair copulations

We examined the claim that sperm competition is an important selection pressure operating in human populations. We recruited 222 men and 194 women to complete a survey of their sexual behaviour. Of these, 28% of men and 22% of women reported engaging in extrapair copulations (EPCs). A review of the literature suggests that rates of extrapair paternity are in the region of 2%. These values suggest that the risk of sperm competition in humans is relatively low, in line with comparative studies of relative testis sizes of humans and other primates. Testis volume was positively correlated with the number of sperm ejaculated. However, we found no support for a recent controversial claim that the within-population frequency distribution of testis size reflects a balanced polymorphism between men who specialize in sperm competition through EPCs and men who are monogamous.     

Magnetic resonance spectroscopy: an in vivo tool for monitoring cerebral injury in SIV-infected macaques

The purpose of our study was to demonstrate the feasibility of using in vivo proton Magnetic Resonance Spectroscopy (MRS) to monitor the brain manifestations of SIV infection in the macaque model of AIDS. Previous spectroscopy work on macaque brain tissue and in vivo work in humans is reviewed to provide the motivation and context for this study. We collected 34 MRS data sets on 14 uninfected rhesus macaques. From this data, we demonstrate that we are capable of detecting changes similar to those observed in human MRS studies for most metabolites using less than 10 animals. The juvenile macaques utilized in this study demonstrate age-related changes in the levels of N-acetyl aspartate (NAA), a neuronal marker. The quantity and distribution of neurochemicals in the macaque are found to be slightly, but significantly, different than in the human.     

Directional freezing as an alternative method for cryopreserving rhesus macaque (Macaca mulatta) sperm

The objective was to develop a freezing protocol using a directional freezing (DF) technique for cryopreservation of rhesus macaque sperm and achieve a survival rate comparable to that achieved with a conventional freezing (CF) technique. Rhesus macaque sperm frozen with a DF technique, with cooling rates of 12 or 16 °C/min, had higher post-thaw motility (P < 0.05) than those cooled at 7 °C/min (59.3, 61.1, and 50.3%, respectively). Furthermore, sperm cryopreserved with 5% glycerol and a DF technique had similar frozen-thawed sperm motility to those cryopreserved by a CF technique (63.7 vs. 53.9%, P > 0.05). The function of sperm cryopreserved at the optimized cooling rate using a DF technique was evaluated by in vitro fertilization of oocytes collected from gonadotropin-stimulated rhesus macaques. Of the 38 mature oocytes collected, 78.9% were fertilized and 71.1, 47.4, and 42.1% of the oocytes developed to the 2-cell, morulae, and blastocyst stages, respectively. In conclusion, rhesus macaque sperm was effectively cryopreserved using a DF technique, providing a new and effective method for genetic preservation in this important species.     

Sperm competition influences sperm size in mammals.

Among mammals sperm competition leads to selection for increased sperm numbers but it is not known whether it also leads to changes in sperm size. Two contrasting theoretical predictions have been made. The first hypothesis relies on the assumption that there is a trade-off between sperm numbers and sperm size and predicts that, in species confronting sperm competition, there will be a concomitant decrease in sperm size as sperm numbers increase. In contrast, the second hypothesis suggests that longer sperm may outcompete rival sperm; if longer sperm may swim faster, they will reach the ova sooner and will be selected when sperm competition prevails. We tested these hypotheses in both primates and rodents. We report that males from species in which females mate promiscuously have longer sperm than species in which females mate with one male. In addition, we also found that sperm length is positively correlated with maximum sperm velocity. Our findings thus support the view that longer sperm may be adaptive in the context of sperm competition.     

Sexual Selection and the Molecular Evolution of ADAM Proteins

Rapid evolution has been identified for many reproductive genes and recent studies have combined phylogenetic tests and information on species mating systems to test sexual selection. Here we examined the molecular evolution of the ADAM gene family, a diverse group of 35 proteins capable of adhesion to and cleavage of other proteins, using sequence data from 25 mammalian genes. Out of the 25 genes analyzed, all those expressed in male reproductive tissue showed evidence of positive selection. Positively selected amino acids within the protein adhesion domain were only found in sperm surface ADAM proteins (ADAMs 1, 2, 3, 4, and 32) suggesting selection driven by male × female interactions. We tested heterogeneity in rates of evolution of the adhesion domain of ADAM proteins by using sequence data from Hominidae and macaques. The use of the branch and branch-site models (PAML) showed evidence of higher d _N/d _S and/or positive selection linked to branches experiencing high postmating selective pressures (chimpanzee and macaque) for Adams 2, 18, and 23. Moreover, we found consistent higher proportion of nonsynonymous relative to synonymous and noncoding sequence substitutions in chimpanzee and/or macaque only for Adams 2, 18, and 23. Our results suggest that lineage-specific sexual selection bouts might have driven the evolution of the adhesion sperm protein surface domains of ADAMs 2 and 18 in primates. Adams 2 and 18 are localized in chromosome 8 of primates and adjacent to each other, so their evolution might have also been influenced by their common genome localization.     

Snail sperm production characteristics vary with sperm competition risk

Sperm competition is widespread and influences both male investment in spermatogenic tissue and ejaculate characteristics. Sperm competition models assume trade-offs between sperm size and number, although such trade-offs may be difficult to detect. This study examines the effects of sperm competition risk on the sperm production characteristics of the freshwater snail Viviparus ater. In this prosobranch, females mate frequently and store sperm, generating sperm competition. Males produce two sperm morphs, fertile eupyrene sperm and non-fertilizing oligopyrene sperm. Non-fertilizing sperm may play a role in sperm competition and therefore, like fertilizing sperm, the number produced could vary relative to sperm competition risk. In addition, trade-offs between sperm number and sperm size may be expected. We manipulated the sex ratio of sexually mature snails and found the presence of rivals affected the ratio of oligopyrene/eupyrene sperm males produced. In experimental and natural populations, the number of oligopyrene sperm produced, but not the number of eupyrene sperm, was significantly higher when the sex ratio was male biased. Testis mass did not vary between experimental treatments. We also found a negative relationship between the number and size of oligopyrene sperm produced, which is consistent with evolutionary models of sperm competition, and is, to our knowledge, the first intraspecific demonstration of a trade-off between these traits.     

The evolution of sperm competition genes: The effect of mating system on levels of genetic variation within and between species

It is widely established that proteins involved in reproduction diverge between species more quickly than other proteins. For male sperm proteins, rapid divergence is believed to be caused by postcopulatory sexual selection and/or sexual conflict. Here, we derive the expected levels of gene diversity within populations and divergence between them for male sperm protein genes evolving by postcopulatory, prezygotic fertility competition, i.e. the function imputed for some sperm and seminal fluid genes. We find that, at the mutation‐selection equilibrium, both gene diversity within species and divergence between them are elevated relative to genes with similar selection coefficients expressed by both sexes. We show that their expected level of diversity is a function of the harmonic mean number of mates per female, which affects the strength of fertility selection stemming from male–male sperm competition. Our predictions provide a null hypothesis for distinguishing between other selective hypotheses accounting for the rapid evolution of male reproductive genes.     

Proteins within the seminal fluid are crucial to keep sperm viable in the honeybee Apis mellifera

Seminal fluid is a biochemically complex mixture of glandular secretions that is transferred to the females sexual tract as part of the ejaculate. Seminal fluid has received increasing scientific interest in the fields of evolutionary and reproductive biology, as it seems a major determinant of male fertility/infertility and reproductive success. Here we used the honeybee Apis mellifera, where seminal fluid can be collected as part of a male's ejaculate, and performed a series of experiments to investigate the effects of seminal fluid and its components on sperm viability. We show that honeybee seminal fluid is highly potent in keeping sperm alive and this positive effect is present over a 24 h time span, comparable to the timing of the sperm storage process in the queen. We furthermore show that the presence of proteins within the seminal fluid and their structural integrity are crucial for this effect. Finally, we activated sperm using fructose and provide evidence that the positive effect of seminal fluid proteins on sperm survival cannot be replicated using generic protein substitutes. Our data provide experimental insights into the complex molecular interplay between sperm and seminal fluid defining male fertility and reproductive success.     

Qualitative Assessment of Macaque Tourist Sites in Padangtegal,Bali, Indonesia,and the Upper Rock Nature Reserve,Gibraltar

Human tourists share space with, touch, feed, and otherwise interact with Macaca at multiple locations. Across Asia and stretching to Gibraltar and Northern Africa, macaques form a substantial tourist attraction as their ranges become increasingly coincident with human use zones. Residing in or as tourist attractions, macaques frequently generate economic benefits to local humans and compete with them for habitat and specific resources. In addition, health conflicts may emerge from increased overlap and interactions between humans and macaques. There is only a handful of studies on the impact, structure, context, and cultural ecology of macaque tourist sites. We provide a general overview of 2 macaque tourist sites, one in Padangtegal, Bali, Indonesia and one in Gibraltar. Qualitative assessment reveals variability in behavioral, ecological, economic, and politically relevant facets of macaque tourism. Specifically, differences in aggression during interactions, potential health dangers, economic factors, and local human perceptions between Padangtegal and Gibraltar suggest that qualitative assessments can assist in our construction of broader models and conceptualizations of the interaction context.     

Ultrasound-guided transfundal uterine sperm recovery from Macaca fascicularis

Previous studies from this center have indicated that the cynomolgus macaque (Macaca fascicularis) may serve as a model for human sperm interaction with the cervix and uterus. In some macaque species, transcervical aspiration of the uterine contents carries a significant risk of disturbing the cervical milieu due to the serpentine nature of the cervix. The only alternatives have been surgical procedures such as laparotomy or laparoscopy. In this paper, we report our experience with a new technique for ultrasound-guided sampling of spermatozoa in the macaque uterus. Twenty adult female cynomolgus macaques were monitored for menses (first day of menses = day l), and one mating per cycle was allowed on day 10, 11, or 12. In one group of ten animals, cervical mucus was sampled at 3 or 18 hr postcoitus (pc) and ultrasound-guided uterine aspiration was performed at 24 hours pc. In a second group of ten monkeys, uterine aspiration was at six hr pc and sperm numbers and motility were counted in the uterine fluid. Uterine fluid was obtained from fourteen of twenty monkeys. Pregnancy occurred in ten of the twenty experimental cycles. Ultrasound-guided uterine aspiration appears to be a reliable method for the evaluation of sperm transport in female macaques. The correlations between uterine sperm recovery and cervical mucus sperm populations arc discussed. The high conception rate in treatment cycles indicates that this procedure can be performed without apparent risk to pregnancy.     

In‐depth proteomic analysis of whole testis tissue from the adult rhesus macaque

The rhesus macaque is similar to humans both anatomically and physiologically as a primate, and has therefore been used extensively in medical and biological research, including reproductive physiology. Despite sequencing of the macaque genome, limited postgenomic studies have been performed to date. In studies aimed at characterizing spermatogenesis, we successfully identified 9078 macaque testis proteins corresponding to 8662 genes, using advanced MS and an optimized proteomics platform, indicative of complex protein compositions during macaque spermatogenesis. Immunohistochemistry analysis further revealed the presence of proteins from different types of testicular cells, including Sertoli cells, Leydig cells, and various stages of germ cells. Our data provide expression evidence at protein level of 3010 protein‐coding genes in 8662 identified testis genes for the first time. We further identified 421 homologous genes from the proteome already known to be essential for male infertility in mouse. Comparative analysis of the proteome showed high similarity with the published human testis proteome, implying that macaque and human may use similar proteins to regulate spermatogenesis. Our in‐depth analysis of macaque spermatogenesis provides a rich resource for further studies, and supports the utility of macaque as a suitable model for the study of human reproduction.     

Evolutionary and biochemical differences between human and monkey acidic mammalian chitinases

Acidic mammalian chitinase (AMCase), an enzyme implicated in the pathology of asthma, is capable of chitin cleavage at a low pH optimum. The corresponding gene (CHIA) can be found in genome databases of a variety of mammals, but the enzyme properties of only the human and mouse proteins were extensively studied. We wanted to compare enzymes of closely related species, such as humans and macaques. In our attempt to study macaque AMCase, we searched for CHIA-like genes in human and macaque genomes. We found that both genomes contain several additional CHIA-like sequences. In humans, CHIA-L1 (hCHIA-L1) is an apparent pseudogene and has the highest homology to CHIA. To determine which of the two genes is functional in monkeys, we assessed their tissue expression levels. In our experiments, CHIA-L1 expression was not detected in human stomach tissue, while CHIA was expressed at high levels. However, in the cynomolgus macaque stomach tissue, the expression pattern of these two genes was reversed: CHIA-L1 was expressed at high levels and CHIA was undetectable. We hypothesized that in macaques CHIA-L1 (mCHIA-L1), and not CHIA, is a gene encoding an acidic chitinase, and cloned it, using the sequence of human CHIA-L1 as a guide for the primer design. We named the new enzyme MACase (Macaca Acidic Chitinase) to emphasize its differences from AMCase. MACase shares a similar tissue expression pattern and pH optimum with human AMCase, but is 50 times more active in our enzymatic activity assay. DNA sequence of the mCHIA-L1 has higher percentage identity to the human pseudogene hCHIA-L1 (91.7%) than to hCHIA (84%). Our results suggest alternate evolutionary paths for human and monkey acidic chitinases.     

A comparison of nuclear and cytoplasmic genetic effects on sperm competitiveness and female remating in a seed beetle

It is widely assumed that male sperm competitiveness evolves adaptively. However, recent studies have found a cytoplasmic genetic component to phenotypic variation in some sperm traits presumed important in sperm competition. As cytoplasmic genes are maternally transmitted, they cannot respond to selection on sperm and this constraint may affect the scope in which sperm competitiveness can evolve adaptively. We examined nuclear and cytoplasmic genetic contributions to sperm competitiveness, using populations of Callosobruchus maculatus carrying orthogonal combinations of nuclear and cytoplasmic lineages. Our design also enabled us to examine genetic contributions to female remating. We found that sperm competitiveness and remating are primarily encoded by nuclear genes. In particular, a male's sperm competitiveness phenotype was contingent on an interaction between the competing male genotypes. Furthermore, cytoplasmic effects were detected on remating but not sperm competitiveness, suggesting that cytoplasmic genes do not generally play a profound evolutionary role in sperm competition.